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LOW POWER ARCHITECTURE AND CIRCUIT TECHNIQUES FOR HIGH BOOST
WIDEBAND GM-C FILTERS
A Thesis
by
MANISHA GAMBHIR
Submitted to the Office of Graduate Studies of Texas A&M University
in partial fulfillment of the requirements for the degree of
MASTER OF SCIENCE
May 2006
Major Subject: Electrical Engineering
LOW POWER ARCHITECTURE AND CIRCUIT TECHNIQUES FOR HIGH BOOST
WIDEBAND GM-C FILTERS
A Thesis
by
MANISHA GAMBHIR
Submitted to the Office of Graduate Studies of Texas A&M University
in partial fulfillment of the requirements for the degree of
MASTER OF SCIENCE
Approved by: Co-Chairs of Committee, Edgar Sanchez-Sinencio
Jose Silva-Martinez Committee Members, Shankar Bhattacharyya Alexander Parlos Head of Department, Costas N. Georghiades
May 2006
Major Subject: Electrical Engineering
iii
ABSTRACT
Low Power Architecture and Circuit Techniques for High Boost Wideband Gm-C
Filters. (May 2006)
Manisha Gambhir, B.E. Delhi University
Co-Chairs of Advisory Committee: Dr. Edgar Sanchez-Sinencio Dr. Jose Silva-Martinez
With the current trend towards integration and higher data rates, read channel
design needs to incorporate significant boost for a wider signal bandwidth. This
dissertation explores the analog design problems associated with design of such
‘Equalizing Filter’ (boost filter) for read channel applications.
Specifically, a 330MHz, 5th order Gm-C continuous time lowpass filter with
24dB boost is designed. Existing architectures are found to be unsuitable for low power,
wideband and high boost operation. The proposed solution realizes boosting zeros by
efficiently combining available transfer functions associated with all nodes of cascaded
biquad cells. Further, circuit techniques suitable for high frequency filter design are
elaborated such as: application of the Gilbert cell as a variable transconductor and a new
Common-Mode-Feedback (CMFB) error amplifier that improves common mode
accuracy without compromising on bandwidth or circuit complexity. A prototype is
fabricated in a standard 0.35µm CMOS process. Experimental results show -41dB of
IM3 for 250mV peak to peak swing with 8.6mW/pole of power dissipation.
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ACKNOWLEDGMENTS
First and foremost, I would like to thank my advisors, Professor E. Sanchez-
Sinencio and Professor J. Silva-Martinez for all the guidance and support that they have
given me. They have been extremely patient and understanding and also have been a
constant source of encouragement for me during my stay here. I have benefitted
tremendously from their insight and knowledge. I would also like to express my
gratitude to the other committee members, Dr. Shankar Bhattacharyya and Dr.
Alexander Parlos for their precious time and valuable suggestions. I would like to thank
my colleages at the Analog Mixed Signals Center, for the interesting and stimulating
discussions we have had, on both technical and non-technical matters. The financial
support received from Agere Systems and SRC is gratefully acknowledged. Lastly, I
would like to thank my parents for all the love and support they have always given me.
v
TABLE OF CONTENTS
CHAPTER Page
I INTRODUCTION..................................................................................................... 1
A. Read Channel Architectures .............................................................................. 2 B. Current Trends in Boost Filter Design .............................................................. 3 C. Organization of the Thesis................................................................................. 4
II FILTER ARCHITECTURE...................................................................................... 6
A. Previous Work on Boost Filter Architectures ................................................... 9 B. A Power Efficient Boost Architecture............................................................... 17 C. Design of Filter’s Parameters ............................................................................ 22
III CIRCUIT IMPLEMENTATION OF OTAS............................................................. 26
A. Core OTA .......................................................................................................... 26 1. Requirements for the Core OTA ..................................................................... 26 2. Proposed Implementation of the Core OTA ................................................... 27 3. Design for Linearity ........................................................................................ 30 4. Design Implementation of the Core OTA ....................................................... 34 B. Boost OTA......................................................................................................... 37 1. Basic Requirements of the Boost OTA ........................................................... 38 2. Possible Implementation of Boost OTA and Previously Reported Structures......................................................................................................... 38 3. Proposed Implementations of the Boost OTA ................................................ 45 4. Design Implementation of the Boost OTA ..................................................... 49
IV CMFB IMPLEMENTATION ................................................................................... 53
A. Common Mode Feedback Scheme.................................................................... 53 B. Conventional CMFB Amplifier......................................................................... 55 C. Proposed CMFB Amplifier and Comparison .................................................... 57
V SIMULATION AND EXPERIMENTAL RESULTS .............................................. 63
A. Simulation Results............................................................................................. 63 B. Layout and Fabrication...................................................................................... 71 C. Experimental Results ......................................................................................... 73
vi
CHAPTER Page
VI SUMMARY AND CONCLUSIONS........................................................................ 80
REFERENCES................................................................................................................... 81
VITA…….. ........................................................................................................................ 85
vii
LIST OF FIGURES
FIGURE Page
1 Disk-Drive read channel system ............................................................................... 2
2 (a) Magnitude response of 5th order Butterworth, 7th order Equiripple delay and a
4th order Inverse Chebyshev filter (ωo = 330MHz) (b) Pole location of the
Equiripple delay filter (c) Pole and zero location for the Inverse Chebyshev
filter ........................................................................................................................... 7
3 S-plane location of poles and zeros for 5th order Butterworth, boost filter............... 9
4 Singly terminated ladder based boost architecture.................................................... 10
5 Node swings at intermediate nodes of the boost architecture based on ladder
structure of Fig. 4 ...................................................................................................... 12
6 (a) Biquad section of the filter reported in [8] (b) The equivalent integrator based
representation ............................................................................................................ 14
7 Equivalent representation of the biquadratic section of Fig. 6(a) ............................. 15
8 Node swings for the biquadratic section shown in Fig. 6 ......................................... 16
9 Conceptual illustration of proposed boost filter architecture .................................... 18
10 Single ended representation of OTA-C implementation of the boost filter .............. 19
11 Group delay error across frequency for -5% to +5% mismatches (varied in steps
of 1%)........................................................................................................................ 22
12 Circuit schematic of the core OTA ........................................................................... 27
13 Source degenerated version of the core OTA ........................................................... 31
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FIGURE Page
14 Small signal model for the core OTA ....................................................................... 34
15 Magnitude and the phase response of the core OTA ................................................ 37
16 Group delay response for a filter with switched OTAs as boost transconductors
(a) 0dB boost (b) 24dB boost setting ........................................................................ 40
17 Conceptual diagram for the programmable integrator .............................................. 41
18 A programmable integrator with fixed bias conditions of the circuit reported in
[16] ............................................................................................................................ 42
19 Multiple transconductors in parallel to realize a programmable OTA [18] .............. 43
20 Switchable unit transconductor cell [18] with constant input and output parasitic .. 44
21 Circuit diagram of boost OTA .................................................................................. 46
22 A possible scheme for discrete control of boost using on-chip DAC ....................... 49
23 Transconductance and phase response of the boost OTA......................................... 52
24 CMFB loop involving two OTAs and a CMFB amplifier ........................................ 54
25 Circuit diagram for a conventional CMFB amplifier................................................ 56
26 (a) Circuit Diagram for the proposed CMFB error Amplifier (b) Its equivalent
representation (c) Low frequency representation (d) High frequency
representation ............................................................................................................ 58
27 Bode plot for (a) conventional CMFB error amplifier (b) proposed CMFB error
amplifier (c) complete CMFB loop ........................................................................... 59
28 AC response of complete CMFB loop ...................................................................... 61
29 Comparison of settling behavior of conventional and proposed CMFB amplifier ... 62
ix
FIGURE Page
30 Magnitude response of the filter with 0-27dB boost................................................. 63
31 Magnitude response of the boost filter across corners .............................................. 64
32 Group delay of the ideal vs. the implemented Butterworth filter (0dB boost
setting) ....................................................................................................................... 65
33 Group delay of the filter for 0dB and 24dB boost setting......................................... 66
34 Transient output for 100MHz sine wave at 0dB boost setting.................................. 67
35 Output spectrum for 100MHz sine wave at 0dB boost setting ................................. 68
36 Output spectrum obtained for intermodulation test at 0dB boost setting.................. 69
37 Output spectrum obtained for intermodulation test at 24dB boost setting................ 70
38 The floorplan of the boost filter IC (not to scale)...................................................... 71
39 Chip micrograph with layout inset ............................................................................ 73
40 The measurement board ............................................................................................ 74
41 Measured transfer function (magnitude) of the filter for varying boost settings ...... 75
42 Measured group delay for 0dB (trace a) and 24dB boost conditions (trace b) ......... 75
43 Intermodulation test for the boost filter with tones at: fO1=304MHz and
fO2=307MHz.............................................................................................................. 76
44 IM3 as a function of average test frequency (fO1+ fO2)/2 .......................................... 77
x
LIST OF TABLES
TABLE Page
1 Comparison of different filter approximations.......................................................... 8
2 Boost gain vs. K ........................................................................................................ 21
3 Relationship between transconductance and capacitances........................................ 23
4 Transconductance and capacitor values .................................................................... 25
5 Comparison of NMOS and CMOS OTA .................................................................. 29
6 Comparison of source degenerated (Fig. 12) and non-degenerated differential pair
Fig. 13) for equal gm and HD3 ................................................................................. 33
7 Aspect ratios and currents for core OTAS ................................................................ 36
8 Aspect ratios and currents for boost OTA................................................................. 51
9 Performance summary based on experimental results .............................................. 77
10 Read channel filters: a comparison ........................................................................... 79
1
CHAPTER I
INTRODUCTION
Popularity of portable applications for consumer electronics has set the focus of
the modern design on low power systems. At the same time, increased demand of
personal computers and interest in gadgets like portable music players, DVD-CD
players, digital cameras and portable notebooks have triggered the rapid evolution of
storage devices.
Storage devices can be classified on the basis of their performance, cost and
maximum capacity. Applications and popularity of a particular medium is mostly
decided by these parameters. Optical disk based storage systems are pervasive in the
segment of software and music distribution. However large access time renders them
ineffective for real time applications. On the other hand flash based systems have access
time in the order of nanoseconds; but are too expensive for storage of Giga-bytes of data
[1]. While recent advances in optical disks systems and flash storage have been
significant, the area of mass storage is still ruled by magnetic disk drives. Hard-disk
drives employed in ever ubiquitous personal-computers, portable notebooks and high
end music players are just few of its applications. In the modern world of portability and
speed, factors like low power consumption, small form factor, high density, and faster
access have become the driving factors for the evolution of Hard Disk Systems.
________________ This thesis follows the format of IEEE Journal of Solid State Circuits.
2
A. Read Channel Architectures
Fig. 1 shows a typical read channel for a disk drive system. It consists of a
magnetic head which relays the read signals to the preamplifier. A variable gain
amplifier is used to control the channel gain. In some architectures, it is also used to
introduce some pre-distortion for MRA (Magnetic Resonance Asymmetry) [2]. Low
pass filter provides necessary anti-aliasing filtering before digitization and may also
embed the equalization gain. Since the dynamic range of the system is quite moderate
(around 40dB) 6 bit of digitization is done using an ADC and the digital bits are passed
to the digital signal processing core. This core adaptively controls the channel gain and
timing loops.
Fig. 1. Disk-Drive read channel system
The magnetic pulses read from the media are essentially Non-Return-to-Zero
(NRZ) format. Earlier read channels used to employ a synchronized peak detector to
VGA
Filter ADC
DSP
Preamp Read Head
Timing Loop
Gain Control Loop
Digital
Output
3
detect the polarity of the pulses. However modern advancements in the read channel
Systems have led to more sophisticated pulse formats and detectors including Partial-
Response-Maximum-Likelihood (PRML) or Extended-PRML (EPRML) detection.
Thus, with increasing recording densities more complex equalization targets have been
used [3]. Further, ever increasing bandwidth implies that the transition between read
pulses have become smaller to give rise to significant Inter Symbol Interference (ISI). In
order to compensate for the channel losses and effectively slim the data pulses, high
frequency boosting is commonly employed in such systems. Channel equalization could
be carried out in the analog and/or digital domain; the partitioning of equalization gain
between analog and digital domains is dictated by system integration issues, complexity
of design and power trade-offs. Any magnitude equalization carried in digital domain
results in boosting of the quantization noise of the ADC that follows the filter [1], thus
degrading the SNR. Therefore it is desirable to embed the maximum boost in the analog
filter. Boost filters provide the necessary low pass filtering before the ADC along with a
programmable high frequency gain for equalization around the cut-off frequency. This
research focuses on different aspects concerning design of this critical block.
B. Current Trends in Boost Filter Design
Need to support high data rates imply wide bandwidths. CMOS wideband gm-C
filters have been reported with bandwidth up to 550MHz [4]; but the boost filter designs
reported so far have confined to the bandwidth of 100-200MHz [5-8] and up to 14dB
4
boost. For high speed, high density data systems, it is desirable to have maximum boost
gain up to 24dB [9]. The design complexity lies with the difficulties associated with
achieving high boost gains for a wideband structure with a reasonable power budget. For
example, a 24dB boost with 330MHz of bandwidth has equivalent gain-bandwidth
product of 5.2GHz while Tf of NMOS devices in a typical 0.35µm technology is less
than 15GHz. The design reported here is a fifth order Butterworth filter with 3dB
bandwidth of 330MHz, a programmable boost of up to 24dB and power dissipation of
43mW.
C. Organization of the Thesis
The thesis has been organized to provide design perspective for architecture as
well as circuit techniques for high frequency filters with programmable boost. The focus
has been kept on the analysis of the new techniques proposed and the issues like
programmability and tuning which can be employed using standard techniques have only
been briefly touched. Chapter II of this paper analyzes previously reported boost
architectures with the aim of finding causes of power efficiency loss in different
approaches. This also forms the basis of deriving a new and power-efficient architecture.
Chapter III outlines the design of transconductors as basic building blocks. Different
considerations regarding the design of core and boost transconductors (OTAs) are
discussed. And application of Gilbert cell as a widely programmable OTA, with constant
input and output parasitic, is illustrated. In Chapter IV a CMFB technique suitable for
5
wideband low power design is introduced. Chapter V elaborates on the simulation and
experimental results obtained while comparing the performance with other reported
filters. It is shown that the reported solution is the most power efficient structure with the
highest boost and bandwidth in the class of filters with similar dynamic range. In
Chapter VI conclusions and future directions are presented.
6
CHAPTER II
FILTER ARCHITECTURE
Choice of filter architecture is dependent on the desired magnitude and phase
response. read channel filters typically use seventh order Equiripple phase
approximation with up to 14dB boost [5-8]. Such choice is based on the fact that
Equiripple response has a flat group delay in the pass band and much beyond. For fast
high data density systems, it is desirable to have maximum boost gain up to 24dB [9].
Approximation with higher magnitude roll-off rate such as Butterworth, or Inverse
Chebyshef approximation may be used provided that the in-band phase error is corrected
using Digital Signal Processing [2].
Fig. 2(a) shows the magnitude response of the 5th order Butterworth, a 7th order
Equiripple delay and a 4th order Inverse Chebyshev approximation (with stop band
rejection of -37dB). Fig. 2(b)-(c) shows the pole zero locations for the seventh order
Equiripple delay and fourth order Inverse Chebyshev transfer function. While the 4th
order Inverse Chebyshev provides a similar attenuation as the 5th order Butterworth at
three times the corner frequency, the later is preferred because of its better group delay
properties. Further, realization of Inverse Chebyshev response requires additional
hardware for the transmission zeros. As illustrated from the plotted responses, a seventh-
order Equiripple delay filter provides an attenuation of -35dB at three times the corner
frequency while a fifth-order Butterworth approximation provides a stop band rejection
of -47dB at such frequency. The filter’s order reduction saves power, die area, and
7
device noise. Thus a 5th order Butterworth approximation is selected over a typical 7th
order Equiripple. The entire magnitude equalization is done in analog while the phase
response of the Butterworth approximation is compensated in the digital domain.
Shifting the phase equalization in digital domain also has the advantage of ease in
scaling with newer technological nodes. Comparisons of these three different filter
approximations are illustrated in table 1.
Fig. 2. (a) Magnitude response of 5th order Butterworth, 7th order Equiripple delay and a
4th order Inverse Chebyshev filter (ωo = 330MHz) (b) Pole location of the Equiripple
delay filter (c) Pole and zero location for the Inverse Chebyshev filter
8
TABLE 1
COMPARISON OF DIFFERENT FILTER APPROXIMATIONS
Attenuation
(at 3ωo) Group Delay
flatness Other factors
5th Order Butterworth -47dB Corrected in digital All pole transfer function
7th Order Equiripple -37dB Best All pole transfer function
4th order Inv-Chebyshev -37dB Worst
Transmission zeros in transfer function
It is desirable that the filter’s group delay response does not change with the
applied boost. For this reason, boosting is done using two real zeros symmetrically
placed around jω axis. Phase of these symmetrically placed zeros cancels each other so
that the phase response of the filter remains independent of the boost setting. This also
enables the phase calibration to be independent of boost setting. Fig. 3 shows the
location of implemented poles and zeros in the complex frequency plane. For a
Butterworth response, all poles are placed on a circle in the s-plane that is centered at the
origin and has a radius ωo. It can be shown that for a 24dB (0dB) boost gain, zeros are to
be placed at 4
ωο± (�).
9
Fig. 3. S-plane location of poles and zeros for 5th order Butterworth, boost filter
Having determined filter’s approximation and the pole-zero constellation,
problem of implementing high boost for wideband structures is analyzed on an
architectural level. Following section focuses on the preciously reported boost
architectures, their analysis from power efficiency perspective and derivation of a
power-efficient architecture which is suitable for implementing high boost gain.
A. Previous Work on Boost Filter Architectures
Filter architectures reported in [5-8] implement boost gain of 12-14dB in 43MHz
to 200MHz bandwidth. This section examines the drawbacks associated with these
ωωωωo/4
10
structures when used for boost gain around 24dB and a bandwidth that exceeds
300MHz.
A single terminated ladder based boost filter is reported in [5] for DVD
applications. The fifth order representation of the reported filter is shown in Fig. 4. Boost
is realized using a feed forward path injecting the current proportional to the input into the
third integrating node.
Fig. 4. Singly terminated ladder based boost architecture
Vout
K1
K2
Vin
C1
C5
C2
C4
C3
Gm1
Gm2
Gm3
Gm4
Gm5 N2
11
Ladder based architecture are typically less sensitive towards temperature and
process variations [10]. However, ladder structures consist of OTA’s that are connected
‘back-to-back’ forming feedback loop amongst two OTA’s. Any transfer-function
shaping using feedforward injection becomes complex as the feedforward path does not
always touches all the feedback loops of the ladder structure. This fact can be easily
followed from Mason’s rule [11] and is mathematically illustrated in context of the
architecture in Fig. 4. The normalized transfer function H(s) for this architecture is given
by:
( ) ( )
)s(DKK1sK
)s(D1K1sK
)s(H 212
212
2 −+−=−+−= (2.1)
where K1 and K2 are the first and second feedforward path gains respectively and D(s)
represents a fifth order function. The intended numerator is of the form: 1sK 22 − . The
input is directly gained and injected into the third integrating node to create the desired
K2s2 term in numerator of (2.1). However K2 path also introduces a low pass feed-
through term -K2 which needs to be cancelled through the additional feedforward path
consisting of K1 (K1 = K2). Since unfiltered input is amplified and injected, all
frequencies see a large gain. Creating large gains at frequencies much lower than the
filter’s cut-off frequency and then canceling this undesired component (using an
additional K1 path) results in loss of power efficiency.
Apart from having an additional cancellation path, injecting amplified low
frequency components through the feedforward path (K2) also has an implication that the
intermediate node such as N2 (Fig. 4) experiences large gains at low frequencies. Fig. 5
12
shows the node swings at intermediate nodes. It is to be noted that the node scaling can
be done to prevent large swings at N2, but only at expense of additional power.
Fig. 5. Node Swings at intermediate nodes of the boost architecture based on ladder
structure of Fig. 4.
The third drawback of such scheme is the fact that the entire boost gain is
embedded in a single gain stage constituting of K2. This implies that for 24dB boost
gain, the transconductance of the boost OTA needs to be 16 times of that of main path
OTA that injects current in to the same node.
13
Another class of boost filters use differentiation as one of the signal shaping
function. A differentiator is used in [6] to inject differentiated input signal into the low
pass node of the biquad to generate two real zeros. While there is no injection of large
low frequency signal currents, keeping the differentiator parasitic poles far away from
ωο significantly increases the power consumption [7]. Also, the entire boost gain is
realized in a single stage using two zeros created by the differentiator, imposing large
power requirements on its realization. The topology employed in [7] makes use of the
differentiator pole as a part of a third order cell and two such cells are used to realize the
complete transfer function. Note that, this topology splits the boost gain amongst two
cells. However, this scheme introduces one real pole for each zero realized by the
differentiator, limiting the types of filter responses that may be realized. For example a
fifth order Butterworth filter cannot be realized using this scheme.
A cascade structure reported in [8] splits the boost gain amongst two biquads,
realizing a zero each. Fig. 6(a) shows the biquad section of this architecture which
implements a single programmable zero apart from second order filtering. The
equivalent representation for this structure using integrators is shown in Fig. 6(b).
14
Fig. 6 (a) Biquad section of the filter reported in [8] (b) The equivalent integrator based
representation
For a better understanding, biquad of Fig. 6(a) can be represented by an
‘equivalent-impedance’ model by observing the emulated impedance at node N12. The
lossy OTA Gm13 is replaced by a resistor (1/Gm13) and the gyrator (Gm12, Gm14,
15
C11) is replaced by an equivalent inductor. Note that, for the simplifying assumption
that node N11 is lossless the gyrator emulates an ideal grounded inductor. Further, the
feedforward integrating path and the programmable boost path of Fig. 6(a) are preserved
to arrive at representation in Fig. 7.
Fig. 7. Equivalent representation of the biquadratic section of Fig. 6(a)
Boost OTA Gm15 injects unfiltered signal current from the input of the biquad
into the output node N12. Low frequency component of this injected current is absorbed
almost entirely by the emulated inductor. This superfluous low frequency current has an
indirect impact on power efficiency. Writing the current equation at low frequency or
DC for node N12 under the simplifying assumption that node N11 is lossless:
Gm15 Vin = Gm12 VN11 @ low frequencies (2.2)
Thus, in absence of any node scaling, the low frequency swing at node N11
increases from the nominal value of unity in accordance to the boost setting.
16
Analytically, the low frequency component of the current generated by Gm15 is supplied
by the gyrator, which makes node N11 experience gain at lower frequencies. The
response of different node for this structure (without node scaling) has been shown in
Fig. 8.
Fig. 8. Node swings for the biquadratic section shown in Fig. 6
If node scaling is employed to alleviate this problem, the transconductor Gm12
has to be as large as the boost OTA, to maintain swings similar to Vin at node N11.
Notice that for 24dB boost, boost OTA is about four times as large as the input OTA and
there are two such biquadratic blocks in the entire filter. Further, parasitic capacitance at
17
node N12 become prohibitively large as it is driven by two large OTAs (Gm15 and
Gm12). Thus, this scaling up of transconductors adversely affects the power efficiency
of this architecture especially when used for wideband filters
B. A Power Efficient Boost Architecture
A power efficient boost filter architecture is derived based on careful analysis of the
demerits of previously discussed architectures. In order to be able to split the boost gain
into two gain stages, cascade based architecture is preferred. The cascaded
representation of the transfer function is given by:
o
o
2o
o2
2oo
2o
o2
2oo
boosts
*
s2Q
s
Ks*
s1Q
s
Ks)s(H
ω+ω
ω+ω
+
ω−ω
ω+ω
+
ω+ω= (2.3-a)
here, Q1 and Q2 refer to the quality factor of biquad 1 and 2 and their values are 0.618
and 1.618 respectively. K determines the placement of zeros and its value ranges from 0
to 16 for 0 to 24dB high frequency boost. Each biquad realizes a real axis zero in
addition to two poles and the gain is split between two stages in cascade.
One way to implement the zeros is to add (subtract) lowpass and bandpass
voltage signals. This is done in [8] by injecting amplified current proportional to the
unfiltered input voltage into the bandpass impedance node (with parallel resonator of a
resistor, capacitor and emulated inductor as in Fig. 7). Alternately, if bandpass current is
added (subtracted) from lowpass current, zeros can be directly constructed without
creating the superfluous low frequency current. Thus, scaling up the transconductors, as
18
explained in previously, is avoided. Conceptual realization (using integrators and
weighted summers) of this scheme is shown in Fig. 9. First four integrators (INT1-4) and
two summers (S1-2) can be realized using cascade of two standard biquads. VLP1,2 and
VBP1,2 in Fig. 9. refer to the lowpass and bandpass nodes of biquad 1,2 respectively and
the variable gain block implements a gain of �K. Bandpass voltage is available in a
standard biquad (by making the first integrator a lossy one) and it can be converted to a
bandpass signal current using a variable boost transconductor. Thus, addition of
bandpass and lowpass signals can be done in current mode by injecting them in the next
integrating node. Since actual summing of lowpass and bandpass signals generated in
biquad1 and biquad2 occur in biquad2 and first order section respectively, equation 2.3-a
can be rewritten as:
o
oo
2o
o2
2oo
2o
o2
2o
boost s)1/Ks(
*s
2Qs
)1/Ks(*
s1Q
s)s(H
ωωω
ωω
ωω
ωωω
++++++++−−−−
++++++++
++++
++++++++==== (2.3-b)
Fig. 9. Conceptual illustration of proposed boost filter architecture
19
The detailed OTA-C implementation (shown as single-ended for easy reading) of
the proposed architecture is shown in Fig. 10. Although biquad 1 and biquad 2 generate
lowpass and bandpass signals for zeros, the actual summing of the signals (in current
domain) occurs at inputs of the biquad 2 and the first order section respectively.
This architecture has two salient features pertaining to power efficiency. Firstly,
each stage realizes a 12dB boost gain and hence the boost path OTAs need only be K1/2
(=4) times Gm12, Gm13. Secondly, there is no cancellation of unwanted currents at low
frequencies. Since the boost OTA injects the band pass current in the next stage, low
frequency swing is always maintained around unity for all the intermediate nodes. Thus,
this architecture does not require scaling up the transconductors as against the one
reported in [8].
Fig. 10. Single ended representation of OTA-C implementation of the boost filter
20
Implementation of this architecture without additional summers requires the 1st
order section to be the last one to provide the current summing node after biquad 2. The
low Q biquad has higher input capacitance than the other biquad (its input OTA is sized
to drive a larger loss-OTA). It is power efficient to keep it at the input of the filter since
the low output impedance of the preceding driver will push the pole location to high
frequency. Given these factors, the order of the sections is optimum if chosen as in Fig.
10, with biquad 1 being the low Q section and 1st order being the last section.
For maximum boost zeros are placed at ωo/4. Hence, the value of K for 24dB
boost is given by:
16K
S/MRad4
350*2
Ko
=
π=ω (2.4)
As a generic case, the value of K for a given boost is given by:
��
���
�
= 6Boost
2K (2.5)
where, boost is expressed in dB. Table 2 shows the values of K for different boost
settings.
21
TABLE 2
BOOST GAINS VS K
Boost (dB) K
2 1.26
4 1.5876
8 2.5198
16 6.3496
24 16
It is instructive to examine the effect of mismatch between the input
transconductance of lowpass and bandpass path of the second and third stage
( 12Gm:12GmK and 13Gm:13GmK ). Assuming that a small additive mismatch factor
∆ is introduced such that the transconductance ratio in the second stage is (1+∆)�K
(instead of �K) and (1-∆)�K in the third stage, the modified transfer function becomes:
��
�
�
��
�
�
ω+ω
∆ωω+ω≈ω
2o
2o
boostMismatchK
K2j1*)j(H)j(H (2.6)
For reasonable mismatch factors (∆ within +/-5%), the effect of change in overall
magnitude response is found to be insignificant. However, zeros influence the phase and
group delay behavior especially at low frequencies. A simulation is performed to
numerically assess the influence of mismatch up to +/-5%. The highest value for K
(=16), is chosen to get maximum group delay sensitivity. Fig. 11 shows that the group
delay error for 5% mismatch is about 85pS for a nominal value of 1560pS at 50MHz
22
(5.45% error). At frequencies higher than this, the error reaches a maximum of 25pS
(1.6% error) and asymptotically vanishes at higher frequencies. Due to adaptive delay
calibration, such small group delay error is easily tolerated in our application.
Fig. 11. Group delay error across frequency for -5% to +5% mismatches (varied in steps
of 1%)
C. Design of Filter’s Parameters
Having determined the filter’s approximation and the architecture, the
transconductances can be expressed in terms of integrating capacitances for given ωo.
Choice of individual transconductance values and capacitance depends on factors like
23
noise consideration, distortion, matching and power budgeting. Table 3 shows the
relationship between different time constants ωi (Gmi/Ci) for the implemented fifth order
Butterworth filter shown in Fig. 10.
TABLE 3
RELATIONSHIP BETWEEN TRANSCONDUCTANCE AND CAPACITANCES
Gm11/C1 = Gm21/C2 = Gm12/C3 = Gm22/C4 = Gm13/C5 = ωo
Gmr1/C1 = ωo /Q1 Gmr2/C3 = ωo /Q2 Gmr3 = Gm13
ωo = 2π∗330 M rad/s
Q1 = 0.618
Q2 =1.618
Boost OTAs’s transconductance = 12GmK , 12GmK
K = 16
For a signal swing of 250mV p-p differential, integrated noise power in the
signal bandwidth of 350MHz needs to be less than 0.78 µV2 to meet SNR specification
of 40dB. For a first hand assumption that all twelve OTAs contribute equally to the noise
power and each OTA has a noise figure of 10, transconductance of each OTA from noise
perspective is calculated to be 737uS. For a maximum gm/C given by table 3 minimum
value of capacitance needed to meet noise consideration can be evaluated. For gm/C of
24
8.8 Grad/s (boost OTA), minimum integrating capacitance of 83 fF is required to meet -
40dB noise specifications.
In general, capacitor values should be minimized in order to increase the power
efficiency. However, one needs to keep in mind the ramifications of choosing small
capacitors. For example, 83 fF integrating capacitance is quite small to meet matching
requirements for a capacitor fabricated in 0.35 µm technology. Further, this also makes
the circuit prone to nonlinearity due significant nonlinear parasitic. It is to be noted that
above analysis is approximate in nature as it assumes all OTAs contribute equal noise
power and does not account for any noise shaping. However, it is does give insight into
the fact that minimum capacitance required for the design of the filter is not noise-
limited; rather it is dictated by considerations such as matching and distortion.
To achieve reasonable matching, minimum fabricated capacitance of 300 fF is
chosen for this technology. Total integration capacitance at a particular node is given by
intentional fabricated capacitor and the parasitic loading capacitances associated with the
node. If loading capacitance at a given node forms a large portion of the total
capacitance, the distortion performance gets severely affected by the loading. It has been
shown that if the parasitic capacitance are kept smaller than one third of the total
integrating capacitance, the effect on the distortion performance is minimum [12].
Having determined the minimum capacitor to be fabricated for the filter, the
individual transconductance and capacitance values need to be determined. Care has
been taken to keep intentional to parasitic capacitance ratio approximately around 3.
Taking into account the parasitic capacitance at various nodes, transconductance and
25
capacitance values can be evaluated for gmi/Ci given in table 4. Individual
transconductance and capacitors are tabulated in table 4.
TABLE 4
TRANSCONDUCTANCE AND CAPACITOR VALUES
Stage Gm (mS)
Capacitor pF
Gm11 2.66 C1 1.15 Gmr1 4.30 C2 0.55 Biquad1 Gm21 1.27 Gm21 1.27 C3 0.55 Gmr2 0.785 C4 1.15 Biquad2 Gm22 2.66 Gm13 1.16 C5 0.5 Stage3 Gmr3 1.16
26
CHAPTER III
CIRCUIT IMPLEMENTATION OF OTAS
A. Core OTA
1. Requirements for the Core OTA
OTA based structures have been highly popular for filters in MHz range due to
the open-loop nature that facilitates the realization of the high frequency functions. One
of the main requirements of the core OTA is its frequency response. It should not have
any poles close to ωo (or the pole frequency of the filter), otherwise the filter’s frequency
response is affected. This requirement stems for the necessity of keeping the filter’s
response ‘butter-worth like’. This also implies that any additional internal high
impedance nodes in the core OTA could be detrimental to the filter’s characteristic.
An ideal OTA has infinite output impedance. Output impedance of the OTA
together with its transconductance gain dictates its DC voltage gain for the resultant
integrator. The DC gain requirement for the OTA for this fifth order Butterworth filter is
quite moderate. It can be shown that for low Q filters, such as Butterworth, filter’s
response is not very sensitive to the DC gain of the integrator [10]. DC gain > 25dB is
sufficient for our application. Further requirements for the OTA include a linearity
specification. Under the assumption that all transconductors contribute equally to the
distortion power, on an average each OTA can contribute up to -49 dB of non-linearity.
27
2. Proposed Implementation of the Core OTA
For moderate dynamic range requirements, a single transistor operating in strong
inversion and saturation region is shown to have highest gm and reasonable tuning range
for a given W/L [13]. Hence, an OTA based on simple differential pair is desired. One
such OTA, based on complementary differential pair is as shown in Fig. 12, is used as
the main transconductor in the filter. Source degenerated version of this OTA has been
reported in [14].
Fig. 12. Circuit schematic of the core OTA
28
The CMOS OTA can be viewed as a NMOS OTA connected in parallel with a
PMOS OTA; so as to facilitate reuse of bias current. One of the most important features
of this OTA is the absence of any internal signal nodes due to its single stage
configuration. This ensures that no additional parasitic poles are introduced. Since the
supply of the overall system is +-1.65V (which gives enough headroom for the
complementary differential pair), complementary differential-pair is an ideal choice for
power-efficiency reasons as well. This structure generates higher value of
transconductance than an NMOS-only differential pair for a given bias current.
However, this does result in increase of the input parasitic capacitance, which could
potentially increase the power requirements of the filter (as increased capacitance
implies increase in transconductance to preserve same ωo). But for the case of OTA-C
filters where parasitic are a fraction of the total integrating capacitance at a given node,
there is an overall increase in power efficiency because of this complementary structure.
It can be shown (using square-law V-I relationship of MOSFET) that the third
harmonic distortion component for a simple differential pair is given by
2GST
2P
3V*32
VHD = (3.1)
where VP is the peak input signal voltage and VGST is the overdrive voltage (VGS-VT)
fixed based on HD3 requirement (<-52dB per OTA for this case). Table 5 compares
simple NMOS differential pair OTA with CMOS OTA (Fig. 12) for a given gm. Let m
be the ratio of PMOS W/L to NMOS W/L of the CMOS OTA. NMOS transistors (for
both the OTAs) are sized so that its VGST is based on minimum value predicted by (3.1)
29
and the total transconductance of the two OTAs is same. Based on these conditions, if
the NMOS transistor of the CMOS OTA is sized W/L, size of NMOS transistors in
NMOS OTA would be L/W)3m
1( + . For small values of m, headroom requirement of
PMOS differential pair (M3,4) increases drastically (partly due to mobility degradation).
On the other hand, for m greater than 3, VGST of the PMOS differential pair becomes less
than the minimum value mentioned above. As a good trade-off between headroom,
power efficiency and total input capacitance, m is chosen to be 1.5. With this value of m,
gm/Id improves by 70% for additional input capacitance of 46% (relative to simple
NMOS OTA) while meeting headroom and HD3 constraints.
TABLE 5
COMPARISON OF NMOS AND CMOS OTA
Parameter NMOS OTA CMOS OTA
LW
LW
3m
1 ��������
����
������������
����
����++++
NMOS =W/L, PMOS = m(W/L)
Id GSTNgmV21
��
�
�
��
�
�+
3m
1
gmV21 GSTN
CINPUT ��
�
�
��
�
�+
3m
1 WLCOX (1+m)WLCOX
gm/Id GSTNV
2
GSTNV2
��
�
�
��
�
�+
3m
1
Supply(MIN) VDSATN5+VGSN1,2+2VP+VDSATP3,4 VDSATN10+VGSN6,7+2VP+VDSATP11 +VGSP8,9
30
Additional advantage of this structure is that the presence of tail current sources,
at both positive and negative supply ends, preserves the supply rejection properties of a
simple differential pair. Its inherent fully-differential nature and the tail current sources
ensure a good low-medium frequency PSRR that is limited only by systematic and
random mismatches amongst the devices. It is to be noted that at higher frequencies,
supply rejection degrades due to the parasitic attributed to the tail current sources.
However, this holds true for a simple differential pair as well.
3. Design for Linearity
It is to be observed that the previously reported implementations of this structure
employed a source degeneration scheme to achieve linearity specifications [14].
However it can be proven that in presence of sufficient headroom, merely increasing
Vdsat with no source degeneration is a more power efficient solution for moderate
linearity applications.
31
VBIAS_P
Vi- Vi+ Vo+ Vo-
M1' M2'
M 3' M4'
M5'
M6'
VDD
VSS
VBIAS_N
R R
RR
Fig. 13. Source degenerated version of the core OTA
Fig. 13 shows the source degenerated version of the complementary OTA. HD3
for a source degenerated simple differential pair can be roughly given by:
22GST
2P
3)1(V*32
VHD
η+= (3.2)
where, 1+ η = 1+gmR is the source degeneration factor and VP is the peak amplitude.
For the CMOS OTA, if NMOS and CMOS differential pair are designed with similar
overdrive voltage (VGST) and degeneration factor (η), the HD3 is expressed as in (3.2).
For PMOS and NMOS differential pair to contribute equally to distortion power, the
overdrive voltages as well as the source degeneration factors are kept same. For equal
32
transconductance of PMOS and NMOS differential pair, this translates to equal values of
source degeneration resistors.
To achieve lower distortion, either source degeneration in form of η can be
introduced or the overdrive voltage can be increased. Assuming that for the case of no
source degeneration i.e. η= 0 (Fig.12), VGST_PMOS = VGST_NMOS = Vdsat1 is required to
achieve a given HD3 specification. Now if we introduce a degeneration of factor 1+η,
the requirement for the overdrive voltage drops to V’GST_PMOS = V’GST_NMOS =
Vdsat1/(1+η). Keeping the same transconductance for both the cases and using the
following square law representation [15], relative sizes and currents for the two cases
(η=0 and finite η), are evaluated:
I = )V1(L2
WVC
GST
GST2
ox
θ+µ (3.3)
gm = )1)(V1(L
WVC
)1()V1(L2
WVC)1)(V1(L
WVC
GST
GSTox2
GST
GST2
ox
GST
GSTox
η+θ+µ
≈η+θ+
θµ−
η+θ+µ (3.4)
where, θ is the fitting parameter that models the mobility degradation due to vertical
electric field. For limiting case of θ = 0, it can be shown that while the current
requirement remains same, size of the driver transistors increase significantly for the
case of the source degenerated differential pair as compared to one with η = 0.
Introduction of additional resistors also results in increase the input referred noise.
Relative expressions for these quantities are tabulated in table 6.
33
TABLE 6
COMPARISON OF SOURCE DEGENERATED (Fig. 12) AND NON-
DEGENERATED (Fig. 13) DIFFERENTIAL PAIR FOR EQUAL GM AND HD3
Parameter Source degenerated No degeneration η = 0
Overdrive VGST/(1+η) VGST
W/L W/L*(1+η)2 W/L
Drain current (Id) Id Id
Noise (Vn2) Vn2 (1+2η)/(1+η)� Vn2
Hence, to achieve required distortion for a given gm, noise and parasitic are less
for the case of increased overdrive voltage as compared to the source-degenerated case.
Increased parasitic for the later case can affect the linearity and indirectly increase the
power consumption of the overall filter. So if head room constraints are met with
increased overdrive voltage, it is preferable not to use any source degeneration. It is to be
noted that choice of increasing the overdrive is advantageous only for the case when
linearity requirements are moderate. For very high overdrive the effect of mobility
degradation becomes pronounced and the headroom becomes prohibitive. For the read-
channel applications a moderate linearity of 40dB is required. For this specification and
0.35µm process, it is possible to design the complementary OTA to meet the distortion
requirements solely by large over-drive voltages rather than resorting to additional
linearization techniques
34
4. Design Implementation of the Core OTA
As mentioned previously, in absence of any additional internal nodes, there are no
parasitic poles associated with this OTA structure. However gate-drain parasitic
capacitors do introduce a feedforward zero that results in negative excess phase. A
simplified small signal model for the OTA is as shown in Fig 14.
gmP + gmNRo Cp
CGD_P + CGD_N
VI
Vo
Fig. 14. Small signal model for the core OTA
Using this model, small signal parameters such as overall transconductance
(Gm), output impedance (Ro) and location of feedforward zero (ωz) can be obtained as
following.
Gm = gmN+ gmP (3.5)
Ro = P N go go
1+
(3.6)
ωz = gd_Ngd_P
PN
C C gm gm
++ (3.7)
35
where gmP and gmN refer to transconductance of P and N type driver devices, goP and
goN refer to output conductance and Cgd_P and Cgd_N refer to the corresponding Gate-
Drain capacitances. Output load and parasitic capacitance are lumped into Cp.
As discussed earlier linearity specifications (-49dB for each of the OTA) is
attained by choosing appropriate overdrive voltage (Vdsat) through equation (3.1).
Overdrive voltage used for the NMOS and PMOS driver transistor in this design is about
250mV. Thus ratio between VP and Vdsat is around 0.5. The transconductance (gm)
requirements for each of the five OTAs have already been specified in Chapter II. For a
specified gm and the overdrive voltage, the size and the bias current for each of the five
OTA can be calculated using the square law approximations in (3.3)-(3.4). A square law
approximation can be used here with fair bit of accuracy because of the fact that Vdsat is
relatively high, thus driver transistors are biased deep in saturation region. Note that
mobility degradation is quite pronounced in this design due to usage of high VGST,
however this effect is captured in the design equations (3.3)-(3.4). Table 7 tabulates bias
current and the size of the driver transistors for all five OTAs. The gm/go for each of the
OTAs is around 100 and parasitic capacitance mostly constituting of Cgs varies from 35
to 150 fF.
36
TABLE 7
ASPECT RATIOS AND CURRENTS FOR CORE OTAS
Aspect Ratios W/L µm
Gm
mS
Bias Current
µA M1 M3 M5 M6
OTA1 (gm11) 2.66 630 4*4.5/0.4 4*7.5/0.4 14*3/0.2 14*30/2
OTA2 (gmr1) 4.3 900 10*2.6/0.4 10*5.2/0.4 20*3/0.4 20*30/2
OTA3 (gm21) 1.27 315 4*2.6/0.4 4*5.2/0.4 7*3/0.4 7*30/2
OTA4 (gm22) 0.78 585 4*3.8/0.4 4*7.5/0.4 13*3/0.4 13*30/2
OTA5 (gm13) 1.16 225 5*1.3/0.4 5*2.5 /0.4 5*3/0.4 5*30/2
Fig. 15 shows the transconductance for OTA 1. The plot is obtained using a
‘short-circuit load’ test, under which the short circuit AC current normalized for 1V AC
input is treated as the transconductance of the OTA. Also shown is the excess phase for
this OTA. Note that the excess phase is less than 4 degree around ωo.
37
Fig. 15. Magnitude and the phase response of the core OTA
B. Boost OTA
Boost OTA is one of the most important building blocks in the entire design. A
high gain associated with the boost path underlines its importance for the performance of
the entire filter. For example, signal passing through the low pass path of the filter sees
a nominal gain of 0dB, however through the boost path it experiences a gain of 24dB (12
db in each biquad).
38
1. Basic Requirements of the Boost OTA
As mentioned in Chapter I, the read channel system can be trained to choose the
best boost gain to minimize the ISI and compensate the channel losses associated with
the programmed data rate. This requirement implies that the boost gain needs to be
programmable and controllable with fine accuracy. For this applications boost gain
needs to be varied from 0 to 24dB with step resolution better than 2dB. Highest boost
setting corresponds to the maximum transconductance of the boost OTA which is 5.1mS
as indicated in Chapter II. Thus, the boost OTA must be programmable over a wide
range: 0 to 5.1mS (0dB boost to 24dB boost) with gain resolution of at least 2dB.
Further requirements for the boost OTA include a stringent linearity specification. It was
earlier shown that on an average each OTA can contribute up to -49 dB as distortion
power.
2. Possible Implementation of Boost OTA and Previously Reported Structures
There have been various techniques proposed for widely programmable high
frequency OTAs [7]-[8]. For these OTAs current through the driver transistor varies in
accordance with the controlled degeneration factor. Hence, as control input (to control
gm) is varied, the input and the output capacitance offered by these OTAs change a lot.
For wideband applications, parasitic capacitors form a significant proportion of the
overall integration capacitance at a given node. Given this premises, use of OTAs whose
39
input or output capacitance varies significantly with control input would be detrimental
to the filter’s performance in two different ways. Firstly the linearity of the filter would
change with boost settings. Secondly Q at the various integrating nodes would change
with boost settings, which manifests itself as change in the shape of the filter’s
magnitude response and a poor group delay. To demonstrate this effect, boost OTA
consisting of multiple sections of complementary differential-pair-OTA, described
earlier in this chapter, are used as boost OTA. Depending on boost setting sections of
this OTA are switched in and out. The filter’s group delay response is plotted for 0dB
boost and maximum boost setting and is shown in Fig. 16. It is evident from this figure
that as input and output capacitance of such boost OTA varies with the boost setting, the
shape of the filter’s response and Q change significantly across boost. Hence it is
desirable to use a programmable OTA whose input and output capacitance remains
invariant across control.
40
Fig. 16. Group delay response for a filter with switched OTAs as boost transconductors
(a) 0dB boost (b) 24dB boost setting
Ratios of controlled impedance can be used to control the transconductance gain.
Fig. 17 shows the block representation of this concept. A widely tunable integrator based
on this concept is used in [16] and is illustrated in Fig. 18.
(a)
(b)
41
VSS
VDD
Vb Vb
Vi+ Vi-Vo+ Vo+R1
R2 R2
Fig. 17. Conceptual diagram for the programmable integrator
The key property of this structure is that it does not change bias condition of the
circuit across the wide tuning range. Thus, it was considered as a potential candidate as
the boost OTA. It is based on steering of the signal current to either the output ( through
FETS M2 and M3) or the cancellation path (through FET M1), in inverse proportion of
controlled impedances. Where M1, M2 and M3 are the transistors operated in triode
region whose impedances are controlled through control voltages VC1 and VC2.
However, the frequency of operation of this structure is limited due to the presence of
multiple nodes and internal feedback.
42
-
+
-
+Vi-
Vo-
VC2
VC1
M1M2 M3
C
R/2 R/2
Bias
CMFB
VDD
VSS
Vo+Vi+
Fig. 18. A programmable integrator with fixed bias conditions of the circuit reported in
[16]
Introduced in [17], is a widely programmable OTA based on a four quadrant
multiplier. The bandwidth of this structure is limited; the use of drivers in linear region
makes this OTA not suitable for wideband operations. In [18], an interesting approach of
using dummy transistor pairs is introduced. Wide programmability of the transconductor
is achieved by switching multiple transconductors connected in parallel (Fig.
19).
43
gm+
-
+-
gm+
-
+-
Vi+
b1
b2
Vi-
Vo-
Vo+
Fig. 19. Multiple transconductors in parallel to realize a programmable OTA [18]
Control inputs (b1 and b2) are used to switch the unit transconductor (Gm1 and
Gm2) in or out of the signal path. The unit transconductor cell is designed such as the
input and output parasitic offered by it remain constant irrespective of the fact whether
that OTA is switched in or not.
Gm1
Gm2
44
b(Vtune)
(1-b)Vtune
(1-b)Vdd
Vcmfb
Vbias
Vcm_ref
Vi+ Vi-
Vo- Vo+
M1 M2M3 M4
M5 M6M7 M8
M9
M10
M11
M12
M13
M14
VDD
Fig. 20. Switchable unit transconductor cell [18] with constant input and output parasitic
The unit transconductor cell that uses an additional dummy transistor pair
connected at the input is shown in Fig. 20. The sum of the bias currents of the main input
pair and the dummy pair is made constant so that the total gate capacitance (CGS-total)
remains same across control setting (b = 0 or 1). However, the signal current generated
in the dummy path does not reach the output. Multiple of such unit cells connected in
parallel are configured to achieve variable transconductance with ‘constant-capacitance’
45
approach. However, if this transconductor is to be used as a boost OTA and the boost
gain is to be varied in fine steps, it would involve many of such elements. This would
not only increases the total gate capacitance (since the overlap capacitances and CGB is
present even in off conditions) but also add to the routing capacitance. Such increase in
parasitic capacitance would seriously impair the bandwidth of the filter, especially when
it is required to drive a large transconductor in the boost path.
3. Proposed Implementations of the Boost OTA
The structure reported here is based on principles of current steering and
cancellation and resembles the well-known Gilbert-cell based mixer. There are two
salient features of this structure: firstly it is widely and continuously programmable. Its
transconductance can easily be programmed from 0 to its maximum value using a
continuous time differential control. Secondly, it preserves the same input and output
capacitance across all boost settings. Fig. 21 shows the schematic of the boost OTA.
The voltage to current conversion is done using the main differential pair (M1-
M2). Two pairs of common-gate control transistors (M3=M4=M5=M6) are used to steer
the signal current generated in the differential pair. These control transistors are driven
by differential boost control voltage (VCNTRL_N,VCNTRL_P) riding over the required
common mode. This common mode signal is generated on chip using a replica circuit. A
differential control voltage is added over this common mode externally to generate
VCNTRL_N and VCNTRL_P on-board.
46
Fig. 21. Circuit diagram of boost OTA
Referring to Fig. 21, for case of 0dB boost the differential input to the control
transistors is zero. Signal current generated by M1-M2 divides between M3-M4 and
M5-M6 equally to the extent to which these devices are matching. Under ideal
conditions, cancellation of the cross-coupled currents in this case implies that no signal
current is output for this setting. Similarly for the highest boost setting, a sufficiently
large differential input at the control port (VCNTRL_N, VCNTRL_P) ensures that the
transistors M3 and M6 are fully on and conduct almost entire of the signal current, while
transistors M4 and M5 slip into cut-off region. Thus, by varying the differential input to
47
the control transistor pairs the fraction of the generated differential signal current that is
allowed to reach the output is controlled. Hence, the OTA can be programmable from 0
to gm_MAX, where gm_MAX is the OTA transconductance when no cancellation occurs.
In contrast, a typical differential pair based practical OTAs provide tuning range of 10-
50% [13].
It is instructive to examine the input and the output capacitance across the boost
setting for the proposed OTA. Ignoring secondary effects, the bias conditions for the
driver transistors (M1-M2) remain the same across boost settings. Therefore, the input
capacitance does not vary across 24dB boost and is roughly given as:
Cin = Cgs M1, M2 (3.8)
Note that the gate-drain capacitance, looking in from the input port, is amplified
by the voltage gain at the drain nodes of driver transistors (M1, M2) due to miller effect.
However since the drains of the driver transistors are low impedance node (Vo has a
large integrating capacitor), the effect of gate-drain capacitance on (3.8) is negligible.
Further the outputs of the boost OTA are well controlled through a common mode
feedback loop and are held at a common mode potential of 0V. The output capacitance
mostly constituting of Cdb, Cgd is given as:
Cout = Cdb M3, M5/ M4, M6 +Cdb M7/M8 + Cgd M3, M5/ M4, M6 (3.9)
Cdb is the voltage dependent junction capacitance which can be modeled as:
Cdb = mj
DB
jo
2Vv
1
C
������������
����������������
����
++++++++
φ
(3.10)
48
where Cj0 is the zero bias junction capacitor and VDB is the junction bias voltage, φ is
the work function, mj is the technological coefficient and v is the instantaneous voltage
across the capacitor. It is to be noted that swing supported by the filter does not change
across the boost setting, thus Cdb� component of the output capacitance shows similar
behavior across the boost setting.
Another important characteristic of the boost OTA is its wideband operation. For
realization of 24dB gain (12 dB in each stage) around 300MHz, the theoretical
requirement on unity gain bandwidth of each of the boost OTA is 4*300MHz = 1.2GHz.
However to ensure a ‘Butterworth-like’ phase response and group delay response, the
parasitic poles need to be place even beyond this limit. The proposed boost OTA does
have an internal node: at the source of common-gate control transistors: M3-M6.
However, this is a low impedance node and the pole due to this node is much beyond the
signal bandwidth. The frequency of this pole is given by impedance (capacitive and
resistive) associated with this node and varies with the boost control. The lowest
frequency of this pole occurs when the large boost control voltage steers the current of
M1/M2 through a single transistor; e.g. M3/M6; in this case, the conductance looking
into this node is roughly given by gm3, where gm3 is the transconductance of transistor
M3 specified for the case of highest boost. Frequency of the additional pole (ωp) is given
by:
4gs1db3sb3gs
3P CCC2C
gm+++
≈ω (3.11)
49
Cgs3 and Csb3 represent gate-source and source-bulk capacitance of M3 and Cdb1
represents drain-bulk capacitance of the driver transistor M1. In practice this pole is
designed to be around 2 GHz.
In a practical implementation, a digital control of the boost can be implemented
using a low resolution on-chip DAC. The concept is illustrated in Fig. 22, where a digital
word is used control the boost in discrete pre-programmed steps.
- + -
+
Vcm
+ Boost Control -
Vin
Boost OTA
DAC
R1
R1
R2
R2
Digital Control Input
Fig. 22. A possible scheme for discrete control of boost using on-chip DAC
4. Design Implementation of the Boost OTA
Procedural details for implementation of the boost OTA follow a similar outline
as that for the core OTA. Gm or the transconductance of the boost cell is specified
earlier in Chapter II. We need a transconductance of 5mS and 3mS for the two boost
50
stages. To meet the distortion specifications, two aspects have been examined. Firstly
the signal current generated through the boost OTA should be sufficiently linear;
secondly the ratio of the intentional to parasitic non linear capacitor at the output node
should be sufficiently large for a linear current to voltage conversion. As discussed
earlier, in this design this ratio is kept at about 3:1. VGST of the driver transistors is
around 200mV. However current source transistors have smaller VGST (�100mV) to meet
the headroom given by ±1.65V supply and input and output swing of 125mV (single-
ended). Given transconductance and VGST, the size (W/L) and the current of the driver
devices are computed using a square law model (3.3)–(3.4) while taking mobility
degradation due to vertical field into account.
For design of the control transistor, the location of the parasitic pole as specified
by equation (3.11) is taken into account. It is to be noted that this equation needs to be
evaluated only for the case of maximum boost, when entire current passing through M1
or M2 (half of the main tail current) passes through one of the control transistors. For the
evaluated transconductance and the current, size of the control transistors are computed
using (3.3)-(3.4). The size of the driver and control transistors are tabulated in table 8.
51
TABLE 8
ASPECT RATIOS AND CURRENTS FOR BOOST OTA
Width (µm)
M1,2
Length (µm)
M1,2
Width (µm)
M3,4,5,6
Length (µm)
M3,4,5,6
Tail Current
mA
Boost OTA1 90 0.4 54 0.4 1.5
Boost OTA2 108 0.4 45 0.4 1.2
Fig. 23 shows the magnitude and the phase response for the transconductance of
the first boost OTA. The transconductance of the boost OTA is simulated using a ‘short-
circuit load’ test. Since the maximum transconductance of the boost OTA is to be
obtained, the boost was set to highest level for this test. From the figure it is evident that
the parasitic pole introduced at the source of the control transistors is around 3GHz. The
error introduced in the group delay due to such pole can be computed to be less than 2%.
Hence it does not affect the system performance much.
52
Fig. 23. Transconductance and phase response of the boost OTA
53
CHAPTER IV
CMFB IMPLEMENTATION
A. Common Mode Feedback Scheme
One of the important aspects of the fully differential circuits is the common mode
control. While the differential mode negative feedback is done to shape the transfer
function, the common mode loop ensures that the circuits operate in a linear region. To
achieve robust Q for the biquads, it is important to maintain constant operating currents
for the OTAs across supply voltage variations, process corners and mismatches. To keep
the current sources from entering the triode region, the common mode voltages must be
maintained accurately. A typical common-mode feedback (CMFB) loop used in the
context of an OTA-C filter is shown in Fig. 24.
The output common mode voltage of OTA1 is sensed at the common source
node of M1’ and M2’. The CMFB error amplifier (AC) compares the sensed common
mode to the ideal common mode voltage and the correction voltage is applied to the gate
of M5. This controls the tail current of the OTA1 which adjusts the common mode
voltage for OTA1. The overall common mode loop is kept under negative feedback for a
stable common mode operation. Vcmref is to be maintained VGS_M1’ lower than the ideal
common mode voltage. A replica of OTA2 is used to generate reference (Vcmref) for the
CMFB amplifier.
54
Fig. 24. CMFB loop involving two OTAs and a CMFB amplifier
Thus the CM accuracy of a system is determined by the common-mode
transconductance gain and the fact that the OTA output has large CM gain is irrelevant
[19]. This fact can be explained as below. Suppose ∆I is the difference between the
currents M5 and M6 (current source transistors of main OTA1 in Fig. 24) would pass
under short circuit load condition. In other words if ∆I is the offset current between the
NMOS and PMOS current source and AC(0) is the DC gain of the EA, the error in the
output CM voltage of OTA1 under closed loop condition is simply given by:
VCM_ERROR = AC(0)*gm5I∆
(4.1)
55
This can be viewed as the offset current being absorbed by the offset voltage
times the DC transconductance gain of the loop (gm5*AC(0)). Thus, the two important
aspects of the CMFB loop design are its DC transconductance gain (gm5*AC(0)) and
open loop unity-gain-bandwidth achieved for a stable loop phase margin. The DC gain
of the error amplifier determines the controllability and accuracy of the DC operating
point while bandwidth determines the frequency range for which the common mode
noise would be effectively rejected. As a conservative specification bandwidth of the
common mode loop can be kept as high as the signal band-width. This ensures that the
CMFB loop would govern the common-mode rejection for the entire signal band.
However, taking into account that the next stage, which is differential in nature, would
also have a finite common mode rejection, the band width specifications can be relaxed.
A common mode band-width of half the signal bandwidth can be chosen as
specification.
B. Conventional CMFB Amplifier
For the typical CMFB loop explained above, the dominant pole is at the output of
the OTA1. All other loop poles need to be placed beyond unity gain bandwidth for a
stable operation. Thus, if a single pole CMFB amplifier is used, its output should be a
low impedance node to maintain pole frequency beyond the unity gain bandwidth of the
loop. This requirement means that typically a low gain amplifier is used as an amplifier
to drive the error to zero where a dominant integrating pole is present in the system. Fig.
56
25 shows a conventional CMFB amplifier. However, with such amplifier it is observed
that the common mode voltages can be in an error of up to +/-100mV for some filter
nodes due to its limited DC gain and offset contribution from several OTAs connected to
those nodes; e,g, the bandpass output of the biquads have the offset contribution of 3
OTAs. Due to limited control of the DC operating point across process corners and
supply voltages, the quality factor associated with different nodes of the filter vary. To
preserve the Butterworth-like shape, an additional Q tuning loop would need to be
introduced if the conventional CMFB amplifier is used.
Fig. 25. Circuit Diagram for a conventional CMFB Amplifier
57
C. Proposed CMFB Amplifier and Comparison
A CMFB amplifier, that is designed to alleviate the above problem by enhancing
the DC gain without compromising on bandwidth and stability, is introduced. The
proposed EA, shown in Fig. 26(a), consists of PMOS input pair (M7,8) with NMOS load
(M9,10) provided with an auxiliary network consisting of a triode-MOS transistor (M12)
with resistance R and a poly capacitor C. The equivalent circuit in Fig. 26(b) shows two
parallel paths. The fast path (1/2*gm7) and the slow path (A2 and gm9) together
determine the DC gain of the EA. At low frequencies, both slow and fast path contribute
to signal gain while at high frequencies only the fast path is active. The low frequency
and high frequency representation of the circuit is illustrated in Fig. 26(c) and Fig. 26(d)
respectively. The purpose of the network around gm9 is to provide high impedance at
low frequencies and low output resistance (1/gm9) at frequencies close to the unity gain
bandwidth of the complete CMFB loop. This characteristic manifests as a low frequency
pole and a zero pair.
If R (M12) is designed such that R >> 1/gm9,10 then the transfer function of the
proposed EA is approximately given by:
( ) L02
L010,90
08,7
'S
CONTROL
CCRRs]CRgmR1RC[s1
2RC
s1Rgm
V
V
++++
��
���
� +−= (4.2)
where RO = 1/(gds7+gds9) and CL = Cgs5+Cdb9+Cdb7. The poles and zero of the error
amplifier are located at:
58
ωp_nw RCRgm
1
010,9≈ , ωz_nw
RC2≈ , ωp_nd1
L
10,9
C
gm≈ (4.3)
Fig.26. (a) Circuit Diagram for the proposed CMFB error Amplifier (b) Its equivalent
representation (c) Low frequency representation (d) High frequency representation
The amplifier’s DC gain is given by –gm7,8R0. ωp_nw is located at low frequency
while ωz_nw is placed at medium frequency. The bode plots of the conventional and the
59
proposed EA are shown in Fig. 27(a) and 27(b) respectively. The proposed EA displays
high DC gain. However, at frequencies greater than ωz_nw, it behaves like the
conventional EA thus retaining similar unity gain bandwidth.
Fig. 27. Bode plot for (a) conventional CMFB error amplifier (b) proposed CMFB error
amplifier (c) complete CMFB loop
In addition to EA’s poles and zeros, overall CMFB loop (see Fig. 24) has a low
frequency pole (ωp_d) at OTA output node and two more non-dominant (high frequency)
poles at common-source node of M1,2 (ωp_nd2) and M1’,2’ (ωp_nd3).
ωp_d14,3
4,36
12,1
2,15
C*gm*2
gds*gds
C*gm*2
gds*gds+≈ , ωp_nd2
8'5'2,'1
'2,'1
CgsCdbCgs*2
gm*2
++≈ ,
ωp_nd352,1
2,1
CdbCgs*2
gm*2
+≈ (4.4)
The overall open-loop gain of the proposed CMFB loop is shown in Figure 27(c).
From the bode plot in trace (c), it can be seen that there are 2 low frequency poles (ωp_d,
60
ωp_nw), 1 zero ωz_nw below unity gain frequency (ωu) and 1 equivalent non-dominant pole
(ωp_eq) above ωu, where ωp_eq represents the combined effect of ωp_nd1, ωp_nd2, and ωp_nd3.
For a typical CMFB loop in this filter, the pole and zero frequencies are: fp_d~200KHz,
fp_nw~400KHz, fz_nw~8MHz, fp_nd1~1GHz, fp_nd2~1.2GHz and fp_nd3>4GHz.
With detailed analysis, it can be shown that ωp_nw and ωz_nw can be designed such
that the following condition for 600 of phase margin holds, hence
��
�
�
��
�
�
��
�
�
��
�
�
ωω
+��
�
�
��
�
�
ωω
+��
�
�
��
�
�
ωω
+≤ω
ω−ω −−−
3nd_p
u1
2nd_p
u1
1nd_p
u1
u
nw_pnw_ztantantan60tan (4.5)
ωu is about 200MHZ for the same CMFB loop mentioned above. Since ωp_nw tracks
ωz_nw (equation 4.3), ωz_nw value of about 1/10th of ωu (or less) is required to satisfy the
inequality (4.5). In order to minimize disturbance in the relative placement of ωp_nw,
ωz_nw and the non-dominant poles across process corners, M12 is biased using a
commonly used circuit shown in Fig. 26(a).
Fig. 28 shows the ac response of the complete CMFB loop under nominal and
extreme corner conditions. The worst case phase margin was observed to be 59.60, while
the worst case unity gain bandwidth is around 180MHz.
Small signal AC response is a good measure of relative stability. But transient
step response is the true test for the absolute stability of a system. Thus a step common
mode disturbance is applied to the CMFB loop to determine its settling behavior.
Further, the common mode current step should be large enough to reflect the realistic
offset and mismatch currents encountered in an IC.
61
Fig. 28. AC response of complete CMFB loop
Common-mode current step equivalent to 25% of the bias current of M1,2 is
applied to each of the nodes Vo1+ and Vo1- in Fig. 24 , and the settling of the presented
CMFB loop is studied. It can be seen from Fig. 29 that the presented amplifier tends to
behave like a single-pole amplifier designed with same bias current for initial few
nanoseconds. However, the final value is more accurate for the proposed amplifier
62
owing to its superior DC gain. The loop’s settling time is around 75 nsecs, which shows
that the zero located at 8 MHz is dominating loop’s transient behavior.
Fig. 29. Comparison of settling behavior of conventional and proposed CMFB amplifier
63
CHAPTER V
SIMULATION AND EXPERIMENTAL RESULTS
A. Simulation Results
Schematic and post layout simulations are performed for verification of the
filter’s performance. Basic simulations of the filter include functionality tests such as AC
response, boost response, transient etc, while performance verification is done using
multi-tone transient simulations with and without boost.
Fig. 30. Magnitude response of the filter with 0-27dB boost
Fig. 30 shows the boost characteristic of the filter using AC simulations. It is
shown that the boost can be varied in continuous steps up to a maximum value of 27dB.
64
Although, the specifications for the maximum boost are 24dB, boost transconductors are
over designed a little bit to meet the specifications across process shifts. Also evident in
the figure is -3dB bandwidth of the filter which is 355MHz. Temperature and process
variations of the magnitude response are shown in Fig. 31. Filter provides at least 24dB
of boost across these variations, while ωo changes from 290MHz to 410MHz.
Fig. 31 Magnitude response of the boost filter across corners
65
Magnitude response serves as a coarse indication of filter’s response. However
how close the realized filter is to a true Butterworth transfer function, can be gauged by
the phase or group delay response of the filter as compared to an ideal model. Fig. 32
shows the group delay response of the filter as compared to an ideal fifth order
Butterworth model based on schematic simulations. Group delay error is within 8% of
the ideal value, which indicates that quality factors of the various nodes are quite close
to the designed values.
Fig. 32. Group delay of the ideal vs. the implemented Butterworth filter (0dB boost
setting)
As discussed earlier, one of the important features of this architecture was
preservation of ‘Butterworth-like’ transfer function across all boost settings. This
property is verified by observing the group delay response across boost. Fig. 33 shows
66
the group delay plot for boost settings of 24dB. Group delay error across boost is < 15%
and can be tolerated in a typical read channel application where adaptive phase
equalization is performed.
Fig. 33. Group delay of the filter for 0dB and 24dB boost setting
While AC simulations are only a representation of the filter’s frequency
selectivity, its true performance can only be ascertained using the transient response to
real world signals. Fig. 34 shows the transient output of the filter when a 250mV p-p
differential sine wave of 100MHz is applied at the input ports. Note that since the filter
has a -1dB gain around 100MHz, for 0dB boost setting, the output swing is at 225mV
peak-peak.
67
Fig. 34. Transient output for 100MHz sine wave at 0dB boost setting
In the end application, the filter is used as an equalizer for read channel where
data pulses are read from magnetic media. Hence, the real-world input to the filter
should be the pulses that are similar to those read from magnetic media. However, sine
wave input can be used to check the harmonic distortion response of the filter. Fig. 35
shows the FFT of the output for the input of 100MHz full swing sine wave. Note that
since filter starts attenuating around 300MHz, a sine wave of frequency 100MHz or less
should be applied for the distortion test, so that at least the third harmonic component is
in-band. The third harmonic distortion is less than -44dB.
68
Fig. 35. Output spectrum for 100MHz sine wave at 0dB boost setting
Distortion specifications are specified for the highest signal frequency and the
largest supported swing. These are the conditions where linearity is worst in a typical
system. Since a single tone test cannot be used to accurately estimate distortion power at
higher end of frequencies (as the third harmonic would fall in the stop-band), multi-tone
tests are used to find intermodulation distortion. A two-tone simulation setup is used
here to find intermodulation distortion. As the maximum possible output swing has
already been specified, the amplitudes of both the inputs are scaled down to half of that
of the single tone source. This ensures that Peak-to-Average ratio (PAR) as well as peak
amplitude remains same as the single-tone test. The two tone chosen are at 300MHz and
310MHz. Their third order intermodulation component is expected to be at 320MHz and
69
290MHz. Fig. 36 shows the resultant FFT obtained when such two tone input is passed
through the filter configured for 0dB boost gain. The obtained IM3 is -45dB.
Fig. 36. Output spectrum obtained for intermodulation test at 0dB boost setting
To qualify the distortion performance across boost, two-tone test was done at the
highest boost setting. It is to be noted that since the output swing of the filter is well
defined at 250mV peak-peak, it should not be made to swing beyond this limit under any
boost setting. For a given boost setting input amplitude should be decreased such that
output signal swing is maintained at this value. Thus, while performing transient
simulations with maximum boost setting, amplitude of both the tones is decreased by
24dB. Fig. 37 shows the results obtained. The third order intermodulation distortion is at
-51dB. Note that IM3 performance seems better for 24dB boost setting than that for 0dB
70
setting. This can be explained as following: With 24dB boost setting, input is scaled
down to maintain nominal swing at the output of the filter, but not all OTAs in the filter
experience a nominal gain. For example input to the biquad 1 would be -24dB down
from the nominal voltage and input to the biquad 2 would be -12 dB down the nominal
voltage. Thus IM3 performance for boost setting seems to be better than the one with
0dB boost setting. Also note that, this is just a simulation-set-up artifact. In the actual
system one does not have to scale down the input at highest boost setting. (As boost gain
cancels the channel attenuation).
Fig. 37. Output spectrum obtained for intermodulation test at 24dB boost setting
71
B. Layout and Fabrication
Layout of the entire filter was done using Cadence Layout Artist software.
Before the layout was done, an elaborate floorplan was designed. The outline of each
sub-block was decided based on the rough estimated area. These outlines were used to
draw a floorplan optimizing the placement of sub-blocks, signal path and power
distribution. Fig. 38 shows the designed floorplan. Notice that the signal path consisting
of Biquad1, Biquad2 and the first order section is folded twice in order to minimize the
total silicon area.
Fig. 38. The floorplan of the boost filter IC (not to scale)
INT 1 INT 2
INT 4
INT 3
INT 5
Boost
OTA 1
Boost
OTA 2
BUFFERS
Input
Outputs
72
Signal lines pass through the middle each sub-block and signal path is kept clean
of any large parasitic. The power lines are routed along the top and bottom boundaries of
the sub-blocks. Since boost transconductors are the largest OTAs, these are placed such
that the parasitic are minimized for their inputs as well as outputs. To drive the input
impedance offered by typical test equipment (50 Ohms), a buffer transconductor is
placed after the filter. A similar buffer is also used in stand-alone calibration path in
order to de-embed the filter’s response from the overall response obtained through the
buffer. Most importantly, the inputs and outputs of the filter as well as calibration path
are placed as near as possible to pad locations. Capacitors are fabricated using 2 poly
layers available in this technology. In order to maintain capacitor ratios across different
nodes, all capacitors are fabricated using arrays of unit cells. Unit cell of 50fF is used.
Rest of the capacitors are array of this unit cells, where the routing pattern is kept similar
across different capacitors to have a true scaling of routing parasitic as well. Dummy
unit cells are used whenever appropriate and array is arranged in the common centroid
patterns. Layout of all the OTAs is done with interleaved fingers of input differential
pair in a common centroid fashion.
The chip micrograph with picture of the filter’s layout in inset is shown in Fig.
39. The power routing was done using thick top metal lines. This not only minimizes the
I-R drop on supplies but also help meet the electromigration rules for high current
density lines. Layout pattern and length of input and the output lines of the main filter
are matched to that of the calibration path in order to minimize mismatches between the
two paths. Finally, dummy metal cells are placed throughout the layout to meet local as
73
BIQUAD1
BIQUAD
1ST ORDER
well as global metal density rules. This prevents over-etching of any isolated thin metal
line when CMP (chemical-mechanical polishing) is performed as the fabrication step.
The chip was packaged in the LQFP 48 pin package.
Fig. 39 Chip micrograph with layout inset
C. Experimental Results
A dual supply of +/-1.65V is used for all experiments. Most of the measurements
were performed using a 500MHz network analyzer. Both signal paths: main filter and
the buffer are characterized. Buffer’s gain is de-embedded from the observed filter’s
response. Fig. 40 shows the picture of the measurement board.
74
Fig. 40. The measurement board
Fig. 41 shows the filter transfer function obtained across various boost settings
after calibration. The -3dB bandwidth measured with 0dB boost setting is 330MHz and
the maximum achievable boost is about 28dB. Fig. 42 shows the group delay response of
the filter; the group delay around cutoff frequency varies by 400pS (16%) between 0dB
to 24dB boost. This is attributed to finite output impedance of OTAs.
75
Fig. 41. Measured transfer function (magnitude) of the filter for varying boost settings
Fig. 42. Measured Group delay for 0dB (trace a) and 24dB boost conditions (trace b)
76
Filter’s linearity performance was measured around the highest frequency of
interest using two-tone intermodulation tests. Fig. 43 shows the spectrum obtained from
this test: two tones are applied at 304MHz and at 307MHz with 250mV of total peak to
peak swing; the boost gain was set at 0dB. The measured third intermodulation
distortion (IM3) is around -41 dB.
Fig. 43. Intermodulation test for the boost filter with tones at: fO1=304MHz and
fO2=307MHz
Intermodulation distortion is characterized for the entire signal band. The two
tones are swept from 100 MHz to 300MHz. Fig. 44 depicts the variation of IM3 for
different frequencies; the frequency spacing of the two tones was 3MHz in all cases.
77
Fig.44. IM3 as a function of average test frequency (fO1+ fO2)/2
The experimental results are summarized in Table 9.
TABLE 9
PERFORMANCE SUMMARY BASED ON EXPERIMENTAL RESULTS
Parameter Value Bandwidth at no boost 330MHz
Maximum Boost 25dB Power 43mW
IM3* (Boost=0dB) -41dB
Output Swing 250mVp-p SNR (Boost=0dB) 49dB
Technology 0.35µm Total Area 0.5mm2
* Measured with two-tones centered at 305MHz and total peak to peak magnitude of
250mV
78
Although it is very difficult to have a fair method of comparison, a reasonable
figure of merit is developed to roughly compare this design with other OTA-C filters
with different boosting factors. A generic figure of merit for continuous time filters in
terms of bandwidth, SNDR, order and power is defined in [20]. In order to accommodate
different boost gains, we need to modify the generic figure of merit. Based on the power
consumption of various blocks it was found that each octave of boost costs as much
power as one of the poles of the filter. Hence, a boost factor equal to the maximum boost
expressed in number of octaves is added to the order of the filter and figure of merit
(FOM) is defined as:
( )Power
FactorBoostOrder*DR*L*BWFOM
+= (5.1)
where BW is the filter’s bandwidth expressed in MHz, SNDR is filter’s signal to noise +
distortion power ratio in linear scale and power is expressed in watts. The minimum
technology size in meter (L) is also included in FOM in order to make a fair comparison
of filters designed in different technologies [21]. Table 10 highlights the comparison
between the design reported here and other filters with boost. It is shown that the design
reported here is a power efficient solution with highest f3dB and highest boosting factor.
79
TABLE 10
READ CHANNEL FILTERS: A COMPARISON
Ref. BW
(MHz)
Boost
(dB)
Filter’s
order
SNDR
(dB)
Technology
Feature
(µm)
Power
(mW)
FOM
[5] 200 13 7 40 0.25 210 22
[6] 50 13 7 40 0.7 40 80.2
[7]** 120 14 8 42 0.25 120 41
[8]* 43 12 7 40 0.6 90 26
This
Work 330 24 5 40 0.35 43 242
* Power includes automatic tuning circuit
** Power includes gm stabilization loop
80
CHAPTER VI
SUMMARY AND CONCLUSIONS
Increasing demand of high data rate systems has driven the rapid evolution of
disk drive technology. Low power, high performance read channel systems have become
critical for this development. This dissertation analyzes one of the most important blocks
of the read channel: a boost filter. Existing architectures for implementation of boost
filters have been analyzed for their merits and demerits and an architectural solution that
can be used to realize low power, high boost wideband filters has been proposed.
Building blocks for the OTA-C filters: the OTA and CMFB loop have been examined in
circuit details with aim to increase the power efficiency of the system. The most popular
wideband OTAs are analyzed and it has been demonstrated that a complementary OTA
is an optimum choice for its power efficiency. A widely programmable OTA for the
boost transconductor, which keeps input and the output capacitance constant across the
boost range, has been designed using well known Gilbert cell. A wideband CMFB
amplifier with high DC gain is also introduced. The architecture and the design concepts
were demonstrated with a silicon prototype of fifth-order Butterworth filter fabricated
using 0.35µm CMOS technology. A 330MHz bandwidth with 24dB boost is obtained for
the power dissipation of 43mW from a 3.3V supply. Third order intermodulation is
obtained to be -41dB. The experimental results are found to agree well with the
simulations.
81
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85
VITA
Manisha Gambhir received her Bachelor of Engineering Degree from the
University of Delhi in 2001. She was employed as IC Design Engineer in Broadband
Silicon Design Center, Texas Instruments India from July 2001 to July 2003, where she
worked on design of analog circuits for an ADSL front end. She joined the graduate
program in the Department of Electrical Engineering, Texas A&M University in the fall
of 2003. She held the position of Engineering Intern with Wireless Group of Silicon
Laboratories, Austin during the summer of 2004. She interned with read channel Group
of Agere Systems, Allentown during the fall of 2005, where she was involved in the
design of high speed ADCs. Her research interests are in the field of high frequency
filters, tuning, data converters and RF circuits. She is presently working towards her
doctorate in the Department of Electrical Engineering, Texas A&M University and can
be reached through the Department of Electrical Engineering, Texas A&M University,
College Station, TX 77843.